1
1
openmpi/configure.ac

1685 строки
54 KiB
Plaintext
Исходник Обычный вид История

2003-11-22 19:36:58 +03:00
# -*- shell-script -*-
#
# Copyright (c) 2004-2005 The Trustees of Indiana University.
# All rights reserved.
# Copyright (c) 2004-2005 The Trustees of the University of Tennessee.
# All rights reserved.
# Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
# University of Stuttgart. All rights reserved.
# Copyright (c) 2004-2005 The Regents of the University of California.
# All rights reserved.
# $COPYRIGHT$
#
# Additional copyrights may follow
#
# $HEADER$
2003-11-22 19:36:58 +03:00
#
############################################################################
# Initialization, version number, and other random setup/init stuff
############################################################################
# Init autoconf
AC_INIT(./ompi/mpi/c/init.c)
AC_PREREQ(2.58)
2003-11-22 19:36:58 +03:00
AC_CONFIG_AUX_DIR(./config)
# Get the version of OMPI that we are installing
OMPI_GET_VERSION($srcdir/VERSION, OMPI)
AC_SUBST(OMPI_MAJOR_VERSION)
AC_SUBST(OMPI_MINOR_VERSION)
AC_SUBST(OMPI_RELEASE_VERSION)
AC_SUBST(OMPI_ALPHA_VERSION)
AC_SUBST(OMPI_BETA_VERSION)
AC_SUBST(OMPI_WANT_SVN)
AC_SUBST(OMPI_SVN_R)
AC_SUBST(OMPI_VERSION)
2003-11-22 19:36:58 +03:00
AC_DEFINE_UNQUOTED(OMPI_MAJOR_VERSION, $OMPI_MAJOR_VERSION,
[Major release number of Open MPI])
AC_DEFINE_UNQUOTED(OMPI_MINOR_VERSION, $OMPI_MINOR_VERSION,
[Major release number of Open MPI])
AC_DEFINE_UNQUOTED(OMPI_RELEASE_VERSION, $OMPI_RELEASE_VERSION,
[Major release number of Open MPI])
AC_DEFINE_UNQUOTED(OMPI_ALPHA_VERSION, $OMPI_ALPHA_VERSION,
[Major release number of Open MPI])
AC_DEFINE_UNQUOTED(OMPI_BETA_VERSION, $OMPI_BETA_VERSION,
[Major release number of Open MPI])
AC_DEFINE_UNQUOTED(OMPI_VERSION, "$OMPI_RELEASE_VERSION",
[Major release number of Open MPI])
# JMS: For the moment, cheat and have ORTE and OPAL version numbers be
# the same. Someday, they will be 3rd part import packages and have
# their own version numbers
ORTE_MAJOR_VERSION="$OMPI_MAJOR_VERSION"
ORTE_MINOR_VERSION="$OMPI_MINOR_VERSION"
ORTE_RELEASE_VERSION="$OMPI_RELEASE_VERSION"
ORTE_ALPHA_VERSION="$OMPI_ALPHA_VERSION"
ORTE_BETA_VERSION="$OMPI_BETA_VERSION"
ORTE_WANT_SVN="$OMPI_WANT_SVN"
ORTE_SVN_R="$OMPI_SVN_R"
ORTE_VERSION="$OMPI_VERSION"
AC_SUBST(ORTE_MAJOR_VERSION)
AC_SUBST(ORTE_MINOR_VERSION)
AC_SUBST(ORTE_RELEASE_VERSION)
AC_SUBST(ORTE_ALPHA_VERSION)
AC_SUBST(ORTE_BETA_VERSION)
AC_SUBST(ORTE_WANT_SVN)
AC_SUBST(ORTE_SVN_R)
AC_SUBST(ORTE_VERSION)
AC_DEFINE_UNQUOTED(ORTE_MAJOR_VERSION, $ORTE_MAJOR_VERSION,
[Major release number of Open RTE])
AC_DEFINE_UNQUOTED(ORTE_MINOR_VERSION, $ORTE_MINOR_VERSION,
[Major release number of Open RTE])
AC_DEFINE_UNQUOTED(ORTE_RELEASE_VERSION, $ORTE_RELEASE_VERSION,
[Major release number of Open RTE])
AC_DEFINE_UNQUOTED(ORTE_ALPHA_VERSION, $ORTE_ALPHA_VERSION,
[Major release number of Open RTE])
AC_DEFINE_UNQUOTED(ORTE_BETA_VERSION, $ORTE_BETA_VERSION,
[Major release number of Open RTE])
AC_DEFINE_UNQUOTED(ORTE_VERSION, "$ORTE_RELEASE_VERSION",
[Major release number of Open RTE])
OPAL_MAJOR_VERSION="$OMPI_MAJOR_VERSION"
OPAL_MINOR_VERSION="$OMPI_MINOR_VERSION"
OPAL_RELEASE_VERSION="$OMPI_RELEASE_VERSION"
OPAL_ALPHA_VERSION="$OMPI_ALPHA_VERSION"
OPAL_BETA_VERSION="$OMPI_BETA_VERSION"
OPAL_WANT_SVN="$OMPI_WANT_SVN"
OPAL_SVN_R="$OMPI_SVN_R"
OPAL_VERSION="$OMPI_VERSION"
AC_SUBST(OPAL_MAJOR_VERSION)
AC_SUBST(OPAL_MINOR_VERSION)
AC_SUBST(OPAL_RELEASE_VERSION)
AC_SUBST(OPAL_ALPHA_VERSION)
AC_SUBST(OPAL_BETA_VERSION)
AC_SUBST(OPAL_WANT_SVN)
AC_SUBST(OPAL_SVN_R)
AC_SUBST(OPAL_VERSION)
AC_DEFINE_UNQUOTED(OPAL_MAJOR_VERSION, $OPAL_MAJOR_VERSION,
[Major release number of OPAL])
AC_DEFINE_UNQUOTED(OPAL_MINOR_VERSION, $OPAL_MINOR_VERSION,
[Major release number of OPAL])
AC_DEFINE_UNQUOTED(OPAL_RELEASE_VERSION, $OPAL_RELEASE_VERSION,
[Major release number of OPAL])
AC_DEFINE_UNQUOTED(OPAL_ALPHA_VERSION, $OPAL_ALPHA_VERSION,
[Major release number of OPAL])
AC_DEFINE_UNQUOTED(OPAL_BETA_VERSION, $OPAL_BETA_VERSION,
[Major release number of OPAL])
AC_DEFINE_UNQUOTED(OPAL_VERSION, "$OPAL_RELEASE_VERSION",
[Major release number of OPAL])
2003-11-22 19:36:58 +03:00
#
# Start it up
#
OMPI_CONFIGURE_SETUP
ompi_show_title "Configuring Open MPI"
ompi_show_subtitle "Checking versions"
AC_MSG_CHECKING([Open MPI version])
AC_MSG_RESULT([$OMPI_VERSION])
AC_MSG_CHECKING([Open MPI Subversion repository version])
AC_MSG_RESULT([$OMPI_SVN_R])
AC_MSG_CHECKING([Open Run-Time Environment (ORTE) version])
AC_MSG_RESULT([$ORTE_VERSION])
AC_MSG_CHECKING([ORTE Subversion repository version])
AC_MSG_RESULT([$ORTE_SVN_R])
AC_MSG_CHECKING([Open Portable Access Layer (OPAL) version])
AC_MSG_RESULT([$OPAL_VERSION])
AC_MSG_CHECKING([OPAL Subversion repository version])
AC_MSG_RESULT([$OPAL_SVN_R])
ompi_show_subtitle "Initialization, setup"
2003-11-22 19:36:58 +03:00
#
# Init automake
# The third argument to AM_INIT_AUTOMAKE surpresses the PACKAGE and
# VERSION macors
#
AM_INIT_AUTOMAKE(openmpi, $OMPI_VERSION, 'no')
2003-11-22 19:36:58 +03:00
#
# GNU C and autotools are inconsistent about whether this is defined
# so let's make it true everywhere for now...
#
AC_GNU_SOURCE
OMPI_TOP_BUILDDIR="`pwd`"
AC_SUBST(OMPI_TOP_BUILDDIR)
2003-11-22 19:36:58 +03:00
cd "$srcdir"
OMPI_TOP_SRCDIR="`pwd`"
AC_SUBST(OMPI_TOP_SRCDIR)
cd "$OMPI_TOP_BUILDDIR"
2003-11-22 19:36:58 +03:00
AC_MSG_NOTICE([builddir: $OMPI_TOP_BUILDDIR])
AC_MSG_NOTICE([srcdir: $OMPI_TOP_SRCDIR])
if test "$OMPI_TOP_BUILDDIR" != "$OMPI_TOP_SRCDIR"; then
2003-11-22 19:36:58 +03:00
AC_MSG_NOTICE([Detected VPATH build])
fi
# Setup the top of the include/ompi_config.h file
2003-11-22 19:36:58 +03:00
AH_TOP([/* -*- c -*-
*
* Copyright (c) 2004-2005 The Trustees of Indiana University.
* All rights reserved.
* Copyright (c) 2004-2005 The Trustees of the University of Tennessee.
* All rights reserved.
* Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
* University of Stuttgart. All rights reserved.
* Copyright (c) 2004-2005 The Regents of the University of California.
* All rights reserved.
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
2003-11-22 19:36:58 +03:00
*
* Function: - OS, CPU and compiler dependent configuration
*/
#ifndef OMPI_CONFIG_H
#define OMPI_CONFIG_H
])
AH_BOTTOM([
#include "ompi_config_bottom.h"
#endif /* OMPI_CONFIG_H */
2003-11-22 19:36:58 +03:00
])
- massive change for module<-->component name fixes throughout the code base. - many (most) mca type names have "component" or "module" in them, as relevant, just to further distinguish the difference between component data/actions and module data/actions. All developers are encouraged to perpetuate this convention when you create types that are specific to a framework, component, or module - did very little to entire framework (just the basics to make it compile) because it's just about to be almost entirely replaced - ditto for io / romio - did not work on elan or ib components; have to commit and then convert those on a different machine with the right libraries and headers - renamed a bunch of *_module.c files to *_component.c and *module*c to *component*c (a few still remain, e.g., ptl/ib, ptl/elan, etc.) - modified autogen/configure/build process to match new filenames (e.g., output static-components.h instead of static-modules.h) - removed DOS-style cr/lf stuff in ns/ns.h - added newline to end of file src/util/numtostr.h - removed some redundant error checking in the top-level topo functions - added a few {} here and there where people "forgot" to put them in for 1 line blocks ;-) - removed a bunch of MPI_* types from mca header files (replaced with corresponding ompi_* types) - all the ptl components had version numbers in their structs; removed - converted a few more elements in the MCA base to use the OBJ interface -- removed some old manual reference counting kruft This commit was SVN r1830.
2004-08-02 04:24:22 +04:00
# Other basic setup stuff (shared with components)
2003-11-22 19:36:58 +03:00
OMPI_BASIC_SETUP
2003-11-22 19:36:58 +03:00
top_ompi_srcdir="$OMPI_TOP_SRCDIR"
AC_SUBST(top_ompi_srcdir)
top_ompi_builddir="$OMPI_TOP_BUILDDIR"
AC_SUBST(top_ompi_builddir)
2003-11-22 19:36:58 +03:00
############################################################################
# Configuration options
############################################################################
OMPI_CONFIGURE_OPTIONS
2003-11-22 19:36:58 +03:00
############################################################################
# Libtool: part one
# (before C compiler setup)
############################################################################
#
# Part one of libtool magic. Enable static so that we have the --with
# tests done up here and can check for OS. Save the values of
# $enable_static and $enable_shared before setting the defaults,
# because if the user specified --[en|dis]able-[static|shared] on the
# command line, they'll already be set. In this way, we can tell if
# the user requested something or if the default was set here.
#
ompi_enable_shared="$enable_shared"
ompi_enable_static="$enable_static"
AM_ENABLE_SHARED
AM_DISABLE_STATIC
2003-11-22 19:36:58 +03:00
WRAPPER_EXTRA_CFLAGS=
WRAPPER_EXTRA_CXXFLAGS=
WRAPPER_EXTRA_FFLAGS=
WRAPPER_EXTRA_FCFLAGS=
WRAPPER_EXTRA_LDFLAGS=
WRAPPER_EXTRA_LIBS=
2003-11-22 19:36:58 +03:00
############################################################################
# Check for compilers and preprocessors
############################################################################
ompi_show_title "Compiler and preprocessor tests"
2003-11-22 19:36:58 +03:00
##################################
# C compiler characteristics
##################################
OMPI_SETUP_CC
2003-11-22 19:36:58 +03:00
#
# Check for some types
#
AC_CHECK_TYPES(long long)
AC_CHECK_TYPES(long double)
AC_CHECK_TYPES(int8_t)
AC_CHECK_TYPES(uint8_t)
AC_CHECK_TYPES(int16_t)
AC_CHECK_TYPES(uint16_t)
AC_CHECK_TYPES(int32_t)
AC_CHECK_TYPES(uint32_t)
AC_CHECK_TYPES(int64_t)
AC_CHECK_TYPES(uint64_t)
AC_CHECK_TYPES(intptr_t)
AC_CHECK_TYPES(uintptr_t)
AC_CHECK_TYPES(mode_t)
#
# Check for type sizes
#
AC_CHECK_SIZEOF(char)
AC_CHECK_SIZEOF(short)
AC_CHECK_SIZEOF(int)
AC_CHECK_SIZEOF(long)
if test $ac_cv_type_long_long = yes; then
AC_CHECK_SIZEOF(long long)
fi
if test $ac_cv_type_long_double = yes; then
AC_CHECK_SIZEOF(long double)
fi
AC_CHECK_SIZEOF(float)
AC_CHECK_SIZEOF(double)
AC_CHECK_SIZEOF(void *)
AC_CHECK_SIZEOF(size_t)
#
# Check for type alignments
#
OMPI_C_GET_ALIGNMENT(char, OMPI_ALIGNMENT_CHAR)
OMPI_C_GET_ALIGNMENT(short, OMPI_ALIGNMENT_SHORT)
OMPI_C_GET_ALIGNMENT(wchar_t, OMPI_ALIGNMENT_WCHAR)
OMPI_C_GET_ALIGNMENT(int, OMPI_ALIGNMENT_INT)
OMPI_C_GET_ALIGNMENT(long, OMPI_ALIGNMENT_LONG)
if test $ac_cv_type_long_long = yes; then
OMPI_C_GET_ALIGNMENT(long long, OMPI_ALIGNMENT_LONG_LONG)
fi
OMPI_C_GET_ALIGNMENT(float, OMPI_ALIGNMENT_FLOAT)
OMPI_C_GET_ALIGNMENT(double, OMPI_ALIGNMENT_DOUBLE)
if test $ac_cv_type_long_double = yes; then
OMPI_C_GET_ALIGNMENT(long double, OMPI_ALIGNMENT_LONG_DOUBLE)
fi
OMPI_C_GET_ALIGNMENT(void *, OMPI_ALIGNMENT_VOID_P)
#
# Does the C compiler native support "bool"? (i.e., without
# <stdbool.h> or any other help)
#
AC_MSG_CHECKING(for C bool type)
AC_COMPILE_IFELSE(AC_LANG_PROGRAM([[
AC_INCLUDES_DEFAULT]],
[[bool bar, foo = true; bar = foo;]]),
[OMPI_NEED_C_BOOL=0 MSG=yes],[OMPI_NEED_C_BOOL=1 MSG=no])
AC_DEFINE_UNQUOTED(OMPI_NEED_C_BOOL, $OMPI_NEED_C_BOOL,
[Whether the C compiler supports "bool" without any other help (such as <stdbool.h>)])
AC_MSG_RESULT([$MSG])
#
# Check for other compiler characteristics
#
if test "$GCC" = "yes"; then
# gcc 2.96 will emit oodles of warnings if you use "inline" with
# -pedantic (which we do in developer builds). However,
# "__inline__" is ok. So we have to force gcc to select the
# right one. If you use -pedantic, the AC_C_INLINE test will fail
# (because it names a function foo() -- without the (void)). So
# we turn off all the picky flags, turn on -ansi mode (which is
# implied by -pedantic), and set warnings to be errors. Hence,
# this does the following (for 2.96):
#
# - causes the check for "inline" to emit a warning, which then
# fails
# - checks for __inline__, which then emits no error, and works
#
# This also works nicely for gcc 3.x because "inline" will work on
# the first check, and all is fine. :-)
CFLAGS_save="$CFLAGS"
CFLAGS="$OMPI_CFLAGS_BEFORE_PICKY -Werror -ansi"
fi
AC_C_INLINE
AC_C_RESTRICT
OMPI_C_WEAK_SYMBOLS
if test "$GCC" = "yes"; then
CFLAGS="$CFLAGS_save"
fi
2003-11-22 19:36:58 +03:00
if test "x$CC" = "xicc"; then
OMPI_CHECK_ICC_VARARGS
fi
# If we want the profiling layer:
# - If the C compiler has weak symbols, use those.
# - If not, then set to compile the code again with #define's in a
# separate directory.
if test "$WANT_WEAK_SYMBOLS" = "0"; then
OMPI_C_HAVE_WEAK_SYMBOLS=0
fi
if test "$WANT_MPI_PROFILING" = "1"; then
if test "$OMPI_C_HAVE_WEAK_SYMBOLS" = "1"; then
OMPI_PROFILING_COMPILE_SEPARATELY=0
else
OMPI_PROFILING_COMPILE_SEPARATELY=1
fi
else
OMPI_PROFILING_COMPILE_SEPARATELY=0
fi
#
# There are 2 layers to the MPI Language binidings One layer generates
# MPI_* bindings. The other layer generates PMPI_* bindings. The
# following conditions determine whether each (or both) these layers
# are built.
# 1. MPI_* bindings are needed if:
# - Profiling is not required
# - Profiling is required but weak symbols are not
# supported
# 2. PMPI_* bindings are needed if profiling is required. Hence we
# define 2 conditionals which tell us whether each of these layers
# need to be built or NOT
#
AM_CONDITIONAL(WANT_MPI_BINDINGS_LAYER,
test "$WANT_MPI_PROFILING" = 0 -o "$OMPI_PROFILING_COMPILE_SEPARATELY" = 1)
AM_CONDITIONAL(WANT_PMPI_BINDINGS_LAYER,
test "$WANT_MPI_PROFILING" = 1)
AM_CONDITIONAL(COMPILE_PROFILING_SEPARATELY,
test "$OMPI_PROFILING_COMPILE_SEPARATELY" = 1)
AC_DEFINE_UNQUOTED(OMPI_ENABLE_MPI_PROFILING, $WANT_MPI_PROFILING,
[Whether we want MPI profiling or not])
AC_DEFINE_UNQUOTED(OMPI_HAVE_WEAK_SYMBOLS, $OMPI_C_HAVE_WEAK_SYMBOLS,
[Wehther we have weak symbols or not])
2003-11-22 19:36:58 +03:00
##################################
# C++ compiler characteristics
##################################
OMPI_SETUP_CXX
2003-11-22 19:36:58 +03:00
# check for type sizes
AC_LANG_SAVE
AC_LANG_CPLUSPLUS
AC_CHECK_SIZEOF(bool)
2003-11-22 19:36:58 +03:00
# check for type alignments
OMPI_C_GET_ALIGNMENT(bool, OMPI_ALIGNMENT_CXX_BOOL)
AC_LANG_RESTORE
2003-11-22 19:36:58 +03:00
# check if we want C++ support
AM_CONDITIONAL(WANT_MPI_CXX_BINDINGS,
test "$WANT_MPI_CXX_SUPPORT" = 1)
AC_DEFINE_UNQUOTED(OMPI_WANT_CXX_BINDINGS, $WANT_MPI_CXX_SUPPORT,
[Whether we want MPI cxx support or not])
##################################
# Assembler Configuration
##################################
ompi_show_subtitle "Assembler"
AM_PROG_AS
OMPI_CONFIG_ASM
2003-11-22 19:36:58 +03:00
##################################
# Fortran
##################################
OMPI_SETUP_F77
OMPI_F77_FIND_EXT_SYMBOL_CONVENTION($OMPI_F77)
# This allows us to mark bogus types, but still have them be a valid
# [sentinel] value
AC_DEFINE([ompi_fortran_bogus_type_t], [int],
[A bogus type that allows us to have sentinel type values that are still valid])
# We want to set the #define's for all of these, so invoke the macros
# regardless of whether we have F77 support or not.
OMPI_F77_CHECK(LOGICAL, LOGICAL, logical, yes,
[char int int32_t], -1)
OMPI_F77_CHECK(INTEGER, INTEGER, integer, yes,
[int32_t int int64_r long:long long], -1)
OMPI_F77_CHECK(INTEGER*1, INTEGER1, integer1, no,
[char int8_t short int int64_t long:long long], 1)
OMPI_F77_CHECK(INTEGER*2, INTEGER2, integer2, no,
[short int16_t int32_t int int64_t long:long long], 2)
OMPI_F77_CHECK(INTEGER*4, INTEGER4, integer4, no,
[int32_t int int64_t long:long long], 4)
OMPI_F77_CHECK(INTEGER*8, INTEGER8, integer8, no,
[int int64_t long:long long], 8)
OMPI_F77_CHECK(INTEGER*16, INTEGER16, integer16, no,
[int int64_t long:long long], 16)
OMPI_F77_CHECK(REAL, REAL, real, yes,
[float double long:double], -1)
OMPI_F77_CHECK(REAL*4, REAL4, real4, no,
[float double long:double], 4)
OMPI_F77_CHECK(REAL*8, REAL8, real8, no,
[float double long:double], 8)
OMPI_F77_CHECK(REAL*16, REAL16, real16, no,
[float double long:double], 16)
OMPI_F77_CHECK(DOUBLE PRECISION, DOUBLE_PRECISION, double_precision, yes,
[float double long:double], -1)
OMPI_F77_CHECK(COMPLEX, COMPLEX, [], yes, [], -1)
# The complex*N tests are a bit different (note: the complex tests are
# the same as all the rest, because complex is a composite of two
# reals, which we *have* to have. It's only the complex*N tests that
# are different). The fortran complex types are composites of the
# real*(N/2) types. So for us to support complex*N, two conditions
# must be true:
#
# a) we must support real*(N/2) (i.e., compiler supports it and we
# have a back-end C type for it)
# b) compiler supports complex*N
OMPI_F77_CHECK(COMPLEX*8, COMPLEX8, [], no, [], 8)
OMPI_F77_CHECK(COMPLEX*16, COMPLEX16, [], no, [], 16)
OMPI_F77_CHECK(COMPLEX*32, COMPLEX32, [], no, [], 32)
# Regardless of whether we have fortran bindings, or even a fortran
# compiler, get the max value for a fortran MPI handle (this macro
# handles the case where we don't have a fortran compiler).
OMPI_F77_GET_FORTRAN_HANDLE_MAX
#
# There are 2 layers to the MPI f77 layer. The only extra thing that
# determine f77 bindings is that fortran can be disabled by user. In
# such cases, we need to not build the target at all. One layer
# generates MPI_f77* bindings. The other layer generates PMPI_f77*
# bindings. The following conditions determine whether each (or both)
# these layers are built.
#
# Superceeding clause:
# - fortran77 bindings should be enabled, else everything is
# disabled
# 1. MPI_f77* bindings are needed if:
# - Profiling is not required
# - Profiling is required but weak symbols are not
# supported
# 2. PMPI_* bindings are needed if profiling is required. Hence we
# define 2 conditionals which tell us whether each of these layers
# need to be built or NOT
#
AM_CONDITIONAL(WANT_MPI_F77_BINDINGS_LAYER,
test \( "$WANT_MPI_PROFILING" = 0 -o "$OMPI_PROFILING_COMPILE_SEPARATELY" = 1 \) -a "$OMPI_WANT_F77_BINDINGS" = 1)
AM_CONDITIONAL(WANT_PMPI_F77_BINDINGS_LAYER,
test "$OMPI_WANT_F77_BINDINGS" = 1 -a "$WANT_MPI_PROFILING" = 1)
#
# Fortran 90 setup
#
OMPI_HAVE_F90_INTEGER1=0
OMPI_HAVE_F90_INTEGER2=0
OMPI_HAVE_F90_INTEGER4=0
OMPI_HAVE_F90_INTEGER8=0
OMPI_HAVE_F90_INTEGER16=0
OMPI_HAVE_F90_REAL4=0
OMPI_HAVE_F90_REAL8=0
OMPI_HAVE_F90_REAL16=0
OMPI_HAVE_F90_COMPLEX8=0
OMPI_HAVE_F90_COMPLEX16=0
OMPI_HAVE_F90_COMPLEX32=0
OMPI_SIZEOF_F90_LOGICAL=0
OMPI_SIZEOF_F90_INT=0
OMPI_SIZEOF_F90_REAL=0
OMPI_SIZEOF_F90_DBLPREC=0
OMPI_SIZEOF_F90_COMPLEX=0
OMPI_SIZEOF_F90_DBLCOMPLEX=0
OMPI_SIZEOF_F90_INT1=0
OMPI_SIZEOF_F90_INT2=0
OMPI_SIZEOF_F90_INT4=0
OMPI_SIZEOF_F90_INT8=0
OMPI_SIZEOF_F90_INT16=0
OMPI_SIZEOF_F90_REAL4=0
OMPI_SIZEOF_F90_REAL8=0
OMPI_SIZEOF_F90_REAL16=0
OMPI_SIZEOF_F90_COMPLEX8=0
OMPI_SIZEOF_F90_COMPLEX16=0
OMPI_SIZEOF_F90_COMPLEX32=0
OMPI_ALIGNMENT_F90_LOGICAL=0
OMPI_ALIGNMENT_F90_INT=0
OMPI_ALIGNMENT_F90_REAL=0
OMPI_ALIGNMENT_F90_DBLPREC=0
OMPI_ALIGNMENT_F90_COMPLEX=0
OMPI_ALIGNMENT_F90_DBLCOMPLEX=0
OMPI_ALIGNMENT_F90_INT1=0
OMPI_ALIGNMENT_F90_INT2=0
OMPI_ALIGNMENT_F90_INT4=0
OMPI_ALIGNMENT_F90_INT8=0
OMPI_ALIGNMENT_F90_INT16=0
OMPI_ALIGNMENT_F90_REAL4=0
OMPI_ALIGNMENT_F90_REAL8=0
OMPI_ALIGNMENT_F90_REAL16=0
OMPI_ALIGNMENT_F90_COMPLEX8=0
OMPI_ALIGNMENT_F90_COMPLEX16=0
OMPI_ALIGNMENT_F90_COMPLEX32=0
OMPI_PRECISION_F90_REAL4=0
OMPI_PRECISION_F90_REAL8=0
OMPI_PRECISION_F90_REAL16=0
OMPI_PRECISION_F90_COMPLEX8=0
OMPI_PRECISION_F90_COMPLEX16=0
OMPI_PRECISION_F90_COMPLEX32=0
OMPI_RANGE_F90_REAL4=0
OMPI_RANGE_F90_REAL8=0
OMPI_RANGE_F90_REAL16=0
OMPI_RANGE_F90_COMPLEX8=0
OMPI_RANGE_F90_COMPLEX16=0
OMPI_RANGE_F90_COMPLEX32=0
OMPI_MPI_OFFSET_KIND=0
OMPI_MPI_ADDRESS_KIND=0
#
# lists of supported Fortran types
#
OMPI_FORTRAN_LKINDS=""
OMPI_FORTRAN_IKINDS=""
OMPI_FORTRAN_RKINDS=""
OMPI_FORTRAN_CKINDS=""
OMPI_SETUP_F90
2003-11-22 19:36:58 +03:00
if test "$OMPI_WANT_F90_BINDINGS" = "0" ; then
OMPI_SIZEOF_F90_LOGICAL=$ac_cv_sizeof_int
OMPI_SIZEOF_F90_INT=$ac_cv_sizeof_int
OMPI_SIZEOF_F90_REAL=$ac_cv_sizeof_float
OMPI_SIZEOF_F90_DBLPREC=$ac_cv_sizeof_double
else
# Look for the fortran module compiler flag
OMPI_F90_FIND_MODULE_INCLUDE_FLAG
# If we want modern Fortran support, then get supported types and sizes
OMPI_F90_CHECK_TYPE(integer(selected_int_kind(2)), OMPI_HAVE_F90_INTEGER1)
if test "$OMPI_HAVE_F90_INTEGER1" = "1"; then
OMPI_FORTRAN_LKINDS="${OMPI_FORTRAN_LKINDS}1 "
OMPI_FORTRAN_IKINDS="${OMPI_FORTRAN_IKINDS}1 "
OMPI_F90_GET_SIZEOF(integer(selected_int_kind(2)),
OMPI_SIZEOF_F90_INT1)
OMPI_F90_GET_ALIGNMENT(integer(selected_int_kind(2)),
OMPI_ALIGNMENT_F90_INT1)
OMPI_F90_GET_SIZEOF(logical(selected_int_kind(2)),
OMPI_SIZEOF_F90_LOGICAL)
OMPI_F90_GET_ALIGNMENT(logical(selected_int_kind(2)),
OMPI_ALIGNMENT_F90_LOGICAL1)
fi
OMPI_F90_CHECK_TYPE(integer(selected_int_kind(4)), OMPI_HAVE_F90_INTEGER2)
if test "$OMPI_HAVE_F90_INTEGER2" = "1"; then
OMPI_FORTRAN_LKINDS="${OMPI_FORTRAN_LKINDS}2 "
OMPI_FORTRAN_IKINDS="${OMPI_FORTRAN_IKINDS}2 "
OMPI_F90_GET_SIZEOF(integer(selected_int_kind(4)),
OMPI_SIZEOF_F90_INT2)
OMPI_F90_GET_ALIGNMENT(integer(selected_int_kind(4)),
OMPI_ALIGNMENT_F90_INT2)
OMPI_F90_GET_SIZEOF(logical(selected_int_kind(4)),
OMPI_SIZEOF_F90_LOGICAL2)
OMPI_F90_GET_ALIGNMENT(logical(selected_int_kind(4)),
OMPI_ALIGNMENT_F90_LOGICAL2)
fi
OMPI_F90_CHECK_TYPE(integer(selected_int_kind(9)), OMPI_HAVE_F90_INTEGER4)
if test "$OMPI_HAVE_F90_INTEGER4" = "1"; then
OMPI_FORTRAN_LKINDS="${OMPI_FORTRAN_LKINDS}4 "
OMPI_FORTRAN_IKINDS="${OMPI_FORTRAN_IKINDS}4 "
OMPI_F90_GET_SIZEOF(integer(selected_int_kind(9)),
OMPI_SIZEOF_F90_INT4)
OMPI_F90_GET_ALIGNMENT(integer(selected_int_kind(9)),
OMPI_ALIGNMENT_F90_INT4)
OMPI_F90_GET_SIZEOF(logical(selected_int_kind(9)),
OMPI_SIZEOF_F90_LOGICAL4)
OMPI_F90_GET_ALIGNMENT(logical(selected_int_kind(9)),
OMPI_ALIGNMENT_F90_LOGICAL4)
fi
OMPI_F90_CHECK_TYPE(integer(selected_int_kind(18)), OMPI_HAVE_F90_INTEGER8)
if test "$OMPI_HAVE_F90_INTEGER8" = "1"; then
OMPI_FORTRAN_LKINDS="${OMPI_FORTRAN_LKINDS}8 "
OMPI_FORTRAN_IKINDS="${OMPI_FORTRAN_IKINDS}8 "
OMPI_F90_GET_SIZEOF(integer(selected_int_kind(18)),
OMPI_SIZEOF_F90_INT8)
OMPI_F90_GET_ALIGNMENT(integer(selected_int_kind(18)),
OMPI_ALIGNMENT_F90_INT8)
OMPI_F90_GET_SIZEOF(logical(selected_int_kind(18)),
OMPI_SIZEOF_F90_LOGICAL8)
OMPI_F90_GET_ALIGNMENT(logical(selected_int_kind(18)),
OMPI_ALIGNMENT_F90_LOGICAL8)
fi
OMPI_F90_CHECK_TYPE(integer(selected_int_kind(19)),
OMPI_HAVE_F90_INTEGER16)
if test "$OMPI_HAVE_F90_INTEGER16" = "1"; then
OMPI_FORTRAN_LKINDS="${OMPI_FORTRAN_LKINDS}16 "
OMPI_FORTRAN_IKINDS="${OMPI_FORTRAN_IKINDS}16 "
OMPI_F90_GET_SIZEOF(integer(selected_int_kind(19)),
OMPI_SIZEOF_F90_INT16)
OMPI_F90_GET_ALIGNMENT(integer(selected_int_kind(19)),
OMPI_ALIGNMENT_F90_INT16)
OMPI_F90_GET_SIZEOF(logical(selected_int_kind(19)),
OMPI_SIZEOF_F90_LOGICAL16)
OMPI_F90_GET_ALIGNMENT(logical(selected_int_kind(19)),
OMPI_ALIGNMENT_F90_LOGICAL16)
fi
OMPI_F90_CHECK_TYPE(real(selected_real_kind(6)), OMPI_HAVE_F90_REAL4)
if test "$OMPI_HAVE_F90_REAL4" = "1"; then
OMPI_HAVE_F90_COMPLEX8=1
OMPI_FORTRAN_RKINDS="${OMPI_FORTRAN_RKINDS}4 "
OMPI_FORTRAN_CKINDS="${OMPI_FORTRAN_CKINDS}4 "
OMPI_F90_GET_SIZEOF(real(selected_real_kind(6)), OMPI_SIZEOF_F90_REAL4)
OMPI_F90_GET_SIZEOF(complex(selected_real_kind(6)),
OMPI_SIZEOF_F90_COMPLEX8)
OMPI_F90_GET_ALIGNMENT(real(selected_real_kind(6)),
OMPI_ALIGNMENT_F90_REAL4)
OMPI_F90_GET_ALIGNMENT(complex(selected_real_kind(6)),
OMPI_ALIGNMENT_F90_COMPLEX8)
OMPI_F90_GET_PRECISION(real(selected_real_kind(6)),
OMPI_PRECISION_F90_REAL4)
OMPI_F90_GET_PRECISION(complex(selected_real_kind(6)),
OMPI_PRECISION_F90_COMPLEX8)
OMPI_F90_GET_RANGE(real(selected_real_kind(6)),
OMPI_RANGE_F90_REAL4)
OMPI_F90_GET_RANGE(complex(selected_real_kind(6)),
OMPI_RANGE_F90_COMPLEX8)
fi
OMPI_F90_CHECK_TYPE(real(selected_real_kind(15)), OMPI_HAVE_F90_REAL8)
if test "$OMPI_HAVE_F90_REAL8" = "1"; then
OMPI_HAVE_F90_COMPLEX16=1
OMPI_FORTRAN_RKINDS="${OMPI_FORTRAN_RKINDS}8 "
OMPI_FORTRAN_CKINDS="${OMPI_FORTRAN_CKINDS}8 "
OMPI_F90_GET_SIZEOF(real(selected_real_kind(15)),
OMPI_SIZEOF_F90_REAL8)
OMPI_F90_GET_SIZEOF(complex(selected_real_kind(15)),
OMPI_SIZEOF_F90_COMPLEX16)
OMPI_F90_GET_ALIGNMENT(real(selected_real_kind(15)),
OMPI_ALIGNMENT_F90_REAL8)
OMPI_F90_GET_ALIGNMENT(complex(selected_real_kind(15)),
OMPI_ALIGNMENT_F90_COMPLEX16)
OMPI_F90_GET_PRECISION(real(selected_real_kind(15)),
OMPI_PRECISION_F90_REAL8)
OMPI_F90_GET_PRECISION(complex(selected_real_kind(15)),
OMPI_PRECISION_F90_COMPLEX16)
OMPI_F90_GET_RANGE(real(selected_real_kind(15)),
OMPI_RANGE_F90_REAL8)
OMPI_F90_GET_RANGE(complex(selected_real_kind(15)),
OMPI_RANGE_F90_COMPLEX16)
fi
OMPI_F90_CHECK_TYPE(real(selected_real_kind(31)), OMPI_HAVE_F90_REAL16)
if test "$OMPI_HAVE_F90_REAL16" = "1"; then
OMPI_HAVE_F90_COMPLEX32=1
OMPI_FORTRAN_RKINDS="${OMPI_FORTRAN_RKINDS}16 "
OMPI_FORTRAN_CKINDS="${OMPI_FORTRAN_CKINDS}16 "
OMPI_F90_GET_SIZEOF(real(selected_real_kind(31)),
OMPI_SIZEOF_F90_REAL16)
OMPI_F90_GET_SIZEOF(complex(selected_real_kind(31)),
OMPI_SIZEOF_F90_COMPLEX32)
OMPI_F90_GET_ALIGNMENT(real(selected_real_kind(31)),
OMPI_ALIGNMENT_F90_REAL16)
OMPI_F90_GET_ALIGNMENT(complex(selected_real_kind(31)),
OMPI_ALIGNMENT_F90_COMPLEX32)
OMPI_F90_GET_PRECISION(real(selected_real_kind(31)),
OMPI_PRECISION_F90_REAL16)
OMPI_F90_GET_PRECISION(complex(selected_real_kind(31)),
OMPI_PRECISION_F90_COMPLEX32)
OMPI_F90_GET_RANGE(real(selected_real_kind(31)),
OMPI_RANGE_F90_REAL16)
OMPI_F90_GET_RANGE(complex(selected_real_kind(31)),
OMPI_RANGE_F90_COMPLEX32)
fi
OMPI_F90_GET_SIZEOF(logical, OMPI_SIZEOF_F90_LOGICAL)
OMPI_F90_GET_ALIGNMENT(logical, OMPI_ALIGNMENT_F90_LOGICAL)
OMPI_F90_GET_SIZEOF(integer, OMPI_SIZEOF_F90_INT)
OMPI_F90_GET_ALIGNMENT(integer, OMPI_ALIGNMENT_F90_INT)
OMPI_F90_GET_SIZEOF(real, OMPI_SIZEOF_F90_REAL)
OMPI_F90_GET_ALIGNMENT(real, OMPI_ALIGNMENT_F90_REAL)
OMPI_F90_GET_SIZEOF(real(kind(1.D0)), OMPI_SIZEOF_F90_DBLPREC)
OMPI_F90_GET_ALIGNMENT(real(kind(1.D0)), OMPI_ALIGNMENT_F90_DBLPREC)
OMPI_F90_GET_SIZEOF(complex, OMPI_SIZEOF_F90_COMPLEX)
OMPI_F90_GET_ALIGNMENT(complex, OMPI_ALIGNMENT_F90_COMPLEX)
OMPI_F90_GET_SIZEOF(complex(kind(1.D0)), OMPI_SIZEOF_F90_DBLCOMPLEX)
OMPI_F90_GET_ALIGNMENT(complex(kind(1.D0)), OMPI_ALIGNMENT_F90_DBLCOMPLEX)
#
# get values for Fortran MPI_OFFSET_KIND and MPI_ADDRESS_KIND
#
OMPI_F90_GET_INT_KIND(18, OMPI_MPI_OFFSET_KIND)
if test "$ac_cv_sizeof_void_p" = "2"; then
OMPI_F90_GET_INT_KIND(4, OMPI_MPI_ADDRESS_KIND)
elif test "$ac_cv_sizeof_void_p" = "4"; then
OMPI_F90_GET_INT_KIND(9, OMPI_MPI_ADDRESS_KIND)
elif test "$ac_cv_sizeof_void_p" = "8"; then
OMPI_F90_GET_INT_KIND(18, OMPI_MPI_ADDRESS_KIND)
elif test "$ac_cv_sizeof_void_p" = "16"; then
OMPI_F90_GET_INT_KIND(19, OMPI_MPI_ADDRESS_KIND)
else
AC_MSG_ERROR([Cannot support Fortran MPI_ADDRESS_KIND!])
fi
fi
#
# Check sizes against what is expected and fix things up
#
if test "$OMPI_SIZEOF_F90_INT1" != "1" ; then
OMPI_SIZEOF_F90_INT1=0
OMPI_ALIGNMENT_F90_INT1=0
OMPI_HAVE_F90_INTEGER1=0
fi
if test "$OMPI_SIZEOF_F90_INT2" != "2" ; then
OMPI_SIZEOF_F90_INT2=0
OMPI_ALIGNMENT_F90_INT2=0
OMPI_HAVE_F90_INTEGER2=0
fi
if test "$OMPI_SIZEOF_F90_INT4" != "4" ; then
OMPI_SIZEOF_F90_INT4=0
OMPI_ALIGNMENT_F90_INT4=0
OMPI_HAVE_F90_INTEGER4=0
fi
if test "$OMPI_SIZEOF_F90_INT8" != "8" ; then
OMPI_SIZEOF_F90_INT8=0
OMPI_ALIGNMENT_F90_INT8=0
OMPI_HAVE_F90_INTEGER8=0
fi
if test "$OMPI_SIZEOF_F90_INT16" != "16" ; then
OMPI_SIZEOF_F90_INT16=0
OMPI_ALIGNMENT_F90_INT16=0
OMPI_HAVE_F90_INTEGER16=0
fi
if test "$OMPI_SIZEOF_F90_REAL4" != "4" ; then
OMPI_SIZEOF_F90_REAL4=0
OMPI_ALIGNMENT_F90_REAL4=0
OMPI_PRECISION_F90_REAL4=0
OMPI_RANGE_F90_REAL4=0
OMPI_HAVE_F90_REAL4=0
fi
if test "$OMPI_SIZEOF_F90_REAL8" != "8" ; then
OMPI_SIZEOF_F90_REAL8=0
OMPI_ALIGNMENT_F90_REAL8=0
OMPI_PRECISION_F90_REAL8=0
OMPI_RANGE_F90_REAL8=0
OMPI_HAVE_F90_REAL8=0
fi
if test "$OMPI_SIZEOF_F90_REAL16" != "16" ; then
OMPI_SIZEOF_F90_REAL16=0
OMPI_ALIGNMENT_F90_REAL16=0
OMPI_PRECISION_F90_REAL16=0
OMPI_RANGE_F90_REAL16=0
OMPI_HAVE_F90_REAL16=0
fi
if test "$OMPI_SIZEOF_F90_COMPLEX8" != "8" ; then
OMPI_SIZEOF_F90_COMPLEX8=0
OMPI_ALIGNMENT_F90_COMPLEX8=0
OMPI_PRECISION_F90_COMPLEX8=0
OMPI_RANGE_F90_COMPLEX8=0
OMPI_HAVE_F90_COMPLEX8=0
fi
if test "$OMPI_SIZEOF_F90_COMPLEX16" != "16" ; then
OMPI_SIZEOF_F90_COMPLEX16=0
OMPI_ALIGNMENT_F90_COMPLEX16=0
OMPI_PRECISION_F90_COMPLEX16=0
OMPI_RANGE_F90_COMPLEX16=0
OMPI_HAVE_F90_COMPLEX16=0
fi
if test "$OMPI_SIZEOF_F90_COMPLEX32" != "32" ; then
OMPI_SIZEOF_F90_COMPLEX32=0
OMPI_ALIGNMENT_F90_COMPLEX32=0
OMPI_PRECISION_F90_COMPLEX32=0
OMPI_RANGE_F90_COMPLEX32=0
OMPI_HAVE_F90_COMPLEX32=0
fi
AC_SUBST(OMPI_FORTRAN_LKINDS)
AC_SUBST(OMPI_FORTRAN_IKINDS)
AC_SUBST(OMPI_FORTRAN_RKINDS)
AC_SUBST(OMPI_FORTRAN_CKINDS)
AC_SUBST(OMPI_SIZEOF_F90_INT1)
AC_SUBST(OMPI_SIZEOF_F90_INT2)
AC_SUBST(OMPI_SIZEOF_F90_INT4)
AC_SUBST(OMPI_SIZEOF_F90_INT8)
AC_SUBST(OMPI_SIZEOF_F90_INT16)
AC_SUBST(OMPI_SIZEOF_F90_REAL4)
AC_SUBST(OMPI_SIZEOF_F90_REAL8)
AC_SUBST(OMPI_SIZEOF_F90_REAL16)
AC_SUBST(OMPI_SIZEOF_F90_COMPLEX8)
AC_SUBST(OMPI_SIZEOF_F90_COMPLEX16)
AC_SUBST(OMPI_SIZEOF_F90_COMPLEX32)
AC_SUBST(OMPI_MPI_OFFSET_KIND)
AC_SUBST(OMPI_MPI_ADDRESS_KIND)
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_INTEGER1, $OMPI_HAVE_F90_INTEGER1,
[support for fortran integer*1])
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_INTEGER2, $OMPI_HAVE_F90_INTEGER2,
[support for fortran integer*2])
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_INTEGER4, $OMPI_HAVE_F90_INTEGER4,
[support for fortran integer*4])
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_INTEGER8, $OMPI_HAVE_F90_INTEGER8,
[support for fortran integer*8])
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_INTEGER16, $OMPI_HAVE_F90_INTEGER16,
[support for fortran integer*16])
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_REAL4, $OMPI_HAVE_F90_REAL4,
[support for fortran real*4])
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_REAL8, $OMPI_HAVE_F90_REAL8,
[support for fortran real*8])
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_REAL16, $OMPI_HAVE_F90_REAL16,
[support for fortran real*16])
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_COMPLEX8, $OMPI_HAVE_F90_COMPLEX8,
[support for fortran complex*8])
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_COMPLEX16, $OMPI_HAVE_F90_COMPLEX16,
[support for fortran complex*16])
AC_DEFINE_UNQUOTED(OMPI_HAVE_F90_COMPLEX32, $OMPI_HAVE_F90_COMPLEX32,
[support for fortran complex*32])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_INT1, $OMPI_SIZEOF_F90_INT1,
[size of fortran integer*1])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_INT2, $OMPI_SIZEOF_F90_INT2,
[size of fortran integer*2])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_INT4, $OMPI_SIZEOF_F90_INT4,
[size of fortran integer*4])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_INT8, $OMPI_SIZEOF_F90_INT8,
[size of fortran integer*8])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_INT16, $OMPI_SIZEOF_F90_INT16,
[size of fortran integer*16])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_REAL4, $OMPI_SIZEOF_F90_REAL4,
[size of fortran real*4])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_REAL8, $OMPI_SIZEOF_F90_REAL8,
[size of fortran real*8])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_REAL16, $OMPI_SIZEOF_F90_REAL16,
[size of fortran real*16])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_COMPLEX8, $OMPI_SIZEOF_F90_COMPLEX8,
[size of fortran complex*8])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_COMPLEX16, $OMPI_SIZEOF_F90_COMPLEX16,
[size of fortran complex*16])
AC_DEFINE_UNQUOTED(OMPI_SIZEOF_F90_COMPLEX32, $OMPI_SIZEOF_F90_COMPLEX32,
[size of fortran complex*32])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_LOGICAL, $OMPI_ALIGNMENT_F90_LOGICAL,
[Alignment of fortran logical])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_INT, $OMPI_ALIGNMENT_F90_INT,
[Alignment of fortran integer])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_REAL, $OMPI_ALIGNMENT_F90_REAL,
[alignment of fortran real])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_DBLPREC, $OMPI_ALIGNMENT_F90_DBLPREC,
[Alignment of fortran double precision])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_COMPLEX, $OMPI_ALIGNMENT_F90_COMPLEX,
[Alignment of fortran complex])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_DBLCOMPLEX,
$OMPI_ALIGNMENT_F90_DBLCOMPLEX,
[Alignment of fortran double complex])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_INT1, $OMPI_ALIGNMENT_F90_INT1,
[alignment of fortran integer*1])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_INT2, $OMPI_ALIGNMENT_F90_INT2,
[alignment of fortran integer*2])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_INT4, $OMPI_ALIGNMENT_F90_INT4,
[alignment of fortran integer*4])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_INT8, $OMPI_ALIGNMENT_F90_INT8,
[alignment of fortran integer*8])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_INT16, $OMPI_ALIGNMENT_F90_INT16,
[alignment of fortran integer*16])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_REAL4, $OMPI_ALIGNMENT_F90_REAL4,
[alignment of fortran real*4])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_REAL8, $OMPI_ALIGNMENT_F90_REAL8,
[alignment of fortran real*8])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_REAL16, $OMPI_ALIGNMENT_F90_REAL16,
[alignment of fortran real*16])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_COMPLEX8, $OMPI_ALIGNMENT_F90_COMPLEX8,
[alignment of fortran complex*8])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_COMPLEX16, $OMPI_ALIGNMENT_F90_COMPLEX16,
[alignment of fortran complex*16])
AC_DEFINE_UNQUOTED(OMPI_ALIGNMENT_F90_COMPLEX32, $OMPI_ALIGNMENT_F90_COMPLEX32,
[alignment of fortran complex*32])
AC_DEFINE_UNQUOTED(OMPI_PRECISION_F90_REAL4, $OMPI_PRECISION_F90_REAL4,
[precision of fortran real*4])
AC_DEFINE_UNQUOTED(OMPI_PRECISION_F90_REAL8, $OMPI_PRECISION_F90_REAL8,
[precision of fortran real*8])
AC_DEFINE_UNQUOTED(OMPI_PRECISION_F90_REAL16, $OMPI_PRECISION_F90_REAL16,
[precision of fortran real*16])
AC_DEFINE_UNQUOTED(OMPI_PRECISION_F90_COMPLEX8, $OMPI_PRECISION_F90_COMPLEX8,
[precision of fortran complex*8])
AC_DEFINE_UNQUOTED(OMPI_PRECISION_F90_COMPLEX16, $OMPI_PRECISION_F90_COMPLEX16,
[precision of fortran complex*16])
AC_DEFINE_UNQUOTED(OMPI_PRECISION_F90_COMPLEX32, $OMPI_PRECISION_F90_COMPLEX32,
[precision of fortran complex*32])
AC_DEFINE_UNQUOTED(OMPI_RANGE_F90_REAL4, $OMPI_RANGE_F90_REAL4,
[range of fortran real*4])
AC_DEFINE_UNQUOTED(OMPI_RANGE_F90_REAL8, $OMPI_RANGE_F90_REAL8,
[range of fortran real*8])
AC_DEFINE_UNQUOTED(OMPI_RANGE_F90_REAL16, $OMPI_RANGE_F90_REAL16,
[range of fortran real*16])
AC_DEFINE_UNQUOTED(OMPI_RANGE_F90_COMPLEX8, $OMPI_RANGE_F90_COMPLEX8,
[range of fortran complex*8])
AC_DEFINE_UNQUOTED(OMPI_RANGE_F90_COMPLEX16, $OMPI_RANGE_F90_COMPLEX16,
[range of fortran complex*16])
AC_DEFINE_UNQUOTED(OMPI_RANGE_F90_COMPLEX32, $OMPI_RANGE_F90_COMPLEX32,
[range of fortran complex*32])
2003-11-22 19:36:58 +03:00
* Rewrite ompi_mca.m4 to use m4_defined lists of projects (ompi, orte, etc.), frameworks, and components without configure scripts instead of hard-coded shell variables (for projects and frameworks) and shell variable building (for components). * Add 3rd category of component configuration (in addition to configure scripts and no-configured components): configure.m4 components. These components can only be built as part of OMPI (like no-configure), but can provide an m4 file that is run as part of the main configure script. These macros can set whether the component should be built, along with just about any other configuration wanted. More care must be taken compared to configure components, as doing things like setting variables or calling AC_MSG_ERROR now affects the top-level configure script (so calling AC_MSG_ERROR if your component can't configure probably isn't what you want) * Added support to autogen.sh for the configure.m4-style components, as well as building up the m4_define lists ompi_mca.m4 now expects * Updated a number of macros to be more config.cache friendly (both so that config.cache can be used and so the test can be quickly run multiple times in the same configrue script): - ompi_config_asm - c_weak_symbols - c_get_alignment * Added new macros to be shared when configuring components: - ompi_objc.m4 (this actually provides AC_PROG_OBJC - don't ask...) - ompi_check_xgrid - ompi_check_tm - ompi_check_bproc * Updated a number of components to use configure.m4 instead of configure.stub - btl portals - io romio - tm ras and pls - bjs, lsf_bproc ras and bproc_seed pls - xgrid ras and pls - null iof (used by tm) This commit was SVN r6412.
2005-07-09 22:52:53 +04:00
# checkpoint results
AC_CACHE_SAVE
2003-11-22 19:36:58 +03:00
##################################
# Header files
##################################
ompi_show_title "Header file tests"
AC_CHECK_HEADERS([alloca.h aio.h arpa/inet.h dirent.h \
dlfcn.h execinfo.h err.h fcntl.h inttypes.h libgen.h \
net/if.h netdb.h netinet/in.h netinet/tcp.h \
poll.h pthread.h pty.h pwd.h sched.h stdint.h \
string.h strings.h stropts.h sys/fcntl.h sys/ipc.h \
sys/ioctl.h sys/mman.h sys/param.h sys/queue.h \
sys/resource.h sys/select.h sys/socket.h sys/sockio.h \
sys/stat.h sys/statvfs.h sys/time.h sys/tree.h \
sys/types.h sys/uio.h sys/utsname.h sys/wait.h syslog.h \
time.h termios.h ulimit.h unistd.h util.h])
# Note that sometimes we have <stdbool.h>, but it doesn't work (e.g.,
# have both Portland and GNU installed; using pgcc will find GNU's
# <stdbool.h>, which all it does -- by standard -- is define "bool" to
# "_Bool" [see
# http://www.opengroup.org/onlinepubs/009695399/basedefs/stdbool.h.html],
# and Portland has no idea what to do with _Bool).
# So first figure out if we have <stdbool.h> (i.e., check the value of
# the macro HAVE_STDBOOL_H from the result of AC_CHECK_HEADERS,
# above). If we do have it, then check to see if it actually works.
# Define OMPI_USE_STDBOOL_H as approrpaite.
AC_CHECK_HEADERS([stdbool.h], [have_stdbool_h=1], [have_stdbool_h=0])
AC_MSG_CHECKING([if <stdbool.h> works])
if test "$have_stdbool_h" = "1"; then
AC_COMPILE_IFELSE(AC_LANG_PROGRAM([[
AC_INCLUDES_DEFAULT
#if HAVE_STDBOOL_H
#include <stdbool.h>
#endif]],
[[bool bar, foo = true; bar = foo;]]),
[OMPI_USE_STDBOOL_H=1 MSG=yes],[OMPI_USE_STDBOOL_H=0 MSG=no])
else
OMPI_USE_STDBOOL_H=0
MSG="no (don't have <stdbool.h>)"
fi
AC_DEFINE_UNQUOTED(OMPI_USE_STDBOOL_H, $OMPI_USE_STDBOOL_H,
[Whether to use <stdbool.h> or not])
AC_MSG_RESULT([$MSG])
2003-11-22 19:36:58 +03:00
* Rewrite ompi_mca.m4 to use m4_defined lists of projects (ompi, orte, etc.), frameworks, and components without configure scripts instead of hard-coded shell variables (for projects and frameworks) and shell variable building (for components). * Add 3rd category of component configuration (in addition to configure scripts and no-configured components): configure.m4 components. These components can only be built as part of OMPI (like no-configure), but can provide an m4 file that is run as part of the main configure script. These macros can set whether the component should be built, along with just about any other configuration wanted. More care must be taken compared to configure components, as doing things like setting variables or calling AC_MSG_ERROR now affects the top-level configure script (so calling AC_MSG_ERROR if your component can't configure probably isn't what you want) * Added support to autogen.sh for the configure.m4-style components, as well as building up the m4_define lists ompi_mca.m4 now expects * Updated a number of macros to be more config.cache friendly (both so that config.cache can be used and so the test can be quickly run multiple times in the same configrue script): - ompi_config_asm - c_weak_symbols - c_get_alignment * Added new macros to be shared when configuring components: - ompi_objc.m4 (this actually provides AC_PROG_OBJC - don't ask...) - ompi_check_xgrid - ompi_check_tm - ompi_check_bproc * Updated a number of components to use configure.m4 instead of configure.stub - btl portals - io romio - tm ras and pls - bjs, lsf_bproc ras and bproc_seed pls - xgrid ras and pls - null iof (used by tm) This commit was SVN r6412.
2005-07-09 22:52:53 +04:00
# checkpoint results
AC_CACHE_SAVE
2003-11-22 19:36:58 +03:00
##################################
# Types
##################################
ompi_show_title "Type tests"
# Size of pid_t
AC_CHECK_SIZEOF(pid_t)
AC_CHECK_TYPES([socklen_t], [AC_DEFINE([HAVE_SOCKLEN_T], [1],
[Whether we have socklen_t or not])],
[], [AC_INCLUDES_DEFAULT
#include <sys/socket.h>])
AC_CHECK_TYPES([struct sockaddr_in], [], [], [AC_INCLUDES_DEFAULT
#ifdef HAVE_NETINET_IN_H
#include <netinet/in.h>
#endif])
# SA_RESTART in signal.h
AC_MSG_CHECKING([if SA_RESTART defined in signal.h])
AC_EGREP_CPP(yes, [
#include <signal.h>
#ifdef SA_RESTART
yes
#endif ], [MSG=yes VALUE=1], [MSG=no VALUE=0])
AC_DEFINE_UNQUOTED(OMPI_HAVE_SA_RESTART, $VALUE,
[Whether we have SA_RESTART in <signal.h> or not])
AC_MSG_RESULT([$MSG])
# sa_len in struct sockaddr
AC_MSG_CHECKING([for sa_len in struct sockaddr])
AC_TRY_COMPILE([#include <sys/types.h>
#include <sys/socket.h>], [struct sockaddr s; s.sa_len;],
[MSG=yes VALUE=1], [MSG=no VALUE=0])
AC_DEFINE_UNQUOTED(OMPI_HAVE_SA_LEN, $VALUE,
[Whether we have the sa_len struct in <sys/socket.h> or not])
AC_MSG_RESULT([$MSG])
AC_CHECK_MEMBERS([struct dirent.d_type], [], [], [
#include <sys/types.h>
#include <dirent.h>])
AC_CHECK_MEMBERS([siginfo_t.si_fd],,,[#include <signal.h>])
# checkpoint results
AC_CACHE_SAVE
2003-11-22 19:36:58 +03:00
##################################
# Libraries
##################################
ompi_show_title "Library and Function tests"
2003-11-22 19:36:58 +03:00
# -lsocket
# -lnsl
# atexit
# getcwd
# atoll
# strtoll
# yield
# vscanf
AC_CHECK_LIB([util], [openpty], [WRAPPER_EXTRA_LIBS="$WRAPPER_EXTRA_LIBS -lutil" LIBLAM_EXTRA_LIBS="$LIBLAMEXTRALIBS -lutil" LIBS="$LIBS -lutil]")
AC_CHECK_FUNCS([asprintf snprintf vasprintf vsnprintf openpty isatty htonl ntohl htons ntohs getpwuid fork waitpid execve pipe setsid mmap])
#
# Make sure we can copy va_lists (need check declared, not linkable)
#
AC_CHECK_DECL(va_copy, OMPI_HAVE_VA_COPY=1, OMPI_HAVE_VA_COPY=0,
[#include <stdarg.h>])
AC_DEFINE_UNQUOTED(OMPI_HAVE_VA_COPY, $OMPI_HAVE_VA_COPY,
[Whether we have va_copy or not])
AC_CHECK_DECL(__va_copy, OMPI_HAVE_UNDERSCORE_VA_COPY=1,
OMPI_HAVE_UNDERSCORE_VA_COPY=0, [#include <stdarg.h>])
AC_DEFINE_UNQUOTED(OMPI_HAVE_UNDERSCORE_VA_COPY, $OMPI_HAVE_UNDERSCORE_VA_COPY,
[Whether we have __va_copy or not])
AC_CHECK_DECLS(__func__)
#
# Solaris has sched_yield in -lrt. Can't use a simple AC_CHECK_LIB,
# though, because Linux has sched_yield in glic (so linking in librt
# will "find" sched_yield, even though it would have been found anyway
# -- so -lrt would be useless [and potentially harmful?] in this
# case).
#
AC_MSG_CHECKING([if we need -lrt for sched_yield])
AC_LINK_IFELSE(AC_LANG_PROGRAM([[extern char *sched_yield;]],
[[char *bar = sched_yield;]]),
[MSG=no],[MSG=not_found])
if test "$MSG" = "not_found"; then
LIBS_save="$LIBS"
LIBS="$LIBS -lrt"
AC_LINK_IFELSE(AC_LANG_PROGRAM([[extern char *sched_yield;]],
[[char *bar = sched_yield;]]),
[MSG=yes],[MSG=not_found])
if test "$MSG" = "not_found"; then
LIBS="$LIBS_save"
fi
fi
AC_MSG_RESULT([$MSG])
# see if we actually have sched_yeild. Use AC_CHECK_FUNCS so that it
# does the glibs "not implemented" check. Will use the current LIBS,
# so will check in -lrt if we decided we needed it above
AC_CHECK_FUNCS([sched_yield])
#
# See if we need the math library explicitly linked in
#
AC_CHECK_LIB([m], [ceil])
* Rewrite ompi_mca.m4 to use m4_defined lists of projects (ompi, orte, etc.), frameworks, and components without configure scripts instead of hard-coded shell variables (for projects and frameworks) and shell variable building (for components). * Add 3rd category of component configuration (in addition to configure scripts and no-configured components): configure.m4 components. These components can only be built as part of OMPI (like no-configure), but can provide an m4 file that is run as part of the main configure script. These macros can set whether the component should be built, along with just about any other configuration wanted. More care must be taken compared to configure components, as doing things like setting variables or calling AC_MSG_ERROR now affects the top-level configure script (so calling AC_MSG_ERROR if your component can't configure probably isn't what you want) * Added support to autogen.sh for the configure.m4-style components, as well as building up the m4_define lists ompi_mca.m4 now expects * Updated a number of macros to be more config.cache friendly (both so that config.cache can be used and so the test can be quickly run multiple times in the same configrue script): - ompi_config_asm - c_weak_symbols - c_get_alignment * Added new macros to be shared when configuring components: - ompi_objc.m4 (this actually provides AC_PROG_OBJC - don't ask...) - ompi_check_xgrid - ompi_check_tm - ompi_check_bproc * Updated a number of components to use configure.m4 instead of configure.stub - btl portals - io romio - tm ras and pls - bjs, lsf_bproc ras and bproc_seed pls - xgrid ras and pls - null iof (used by tm) This commit was SVN r6412.
2005-07-09 22:52:53 +04:00
# checkpoint results
AC_CACHE_SAVE
2003-11-22 19:36:58 +03:00
##################################
# System-specific tests
##################################
ompi_show_title "System-specific tests"
#
# Test to determine type of MPI_Offset. This is searched in the following order
# int64_t, long long, long, int. If none of these are 8 bytes, then we should
# search for int32_t, long long, long, int.
#
MPI_OFFSET_TYPE="not found"
MPI_OFFSET_DATATYPE="not found"
AC_MSG_CHECKING([checking for type of MPI_Offset])
if test "$ac_cv_type_long_long" = "yes" -a "$ac_cv_sizeof_long_long" = 8; then
MPI_OFFSET_TYPE="long long"
MPI_OFFSET_DATATYPE=MPI_LONG_LONG
MPI_OFFSET_SIZE=8
elif test "$ac_cv_type_long" = "yes" -a "$ac_cv_sizeof_long" = 8; then
MPI_OFFSET_TYPE="long"
MPI_OFFSET_DATATYPE=MPI_LONG
MPI_OFFSET_SIZE=8
elif test "ac_cv_sizeof_int" = 8; then
MPI_OFFSET_TYPE=int
MPI_OFFSET_DATATYPE=MPI_INT
MPI_OFFSET_SIZE=8
elif test "$ac_cv_type_long_long" = "yes" -a "$ac_cv_sizeof_long_long" = 4; then
MPI_OFFSET_TYPE="long long"
MPI_OFFSET_DATATYPE=MPI_LONG_LONG
MPI_OFFSET_SIZE=4
elif test "$ac_cv_type_long" = "yes" -a "$ac_cv_sizeof_long" = 4; then
MPI_OFFSET_TYPE="long"
MPI_OFFSET_DATATYPE=MPI_LONG
MPI_OFFSET_SIZE=4
elif test "ac_cv_sizeof_int" = 4; then
MPI_OFFSET_TYPE=int
MPI_OFFSET_DATATYPE=MPI_INT
MPI_OFFSET_SIZE=4
fi
AC_MSG_RESULT([$MPI_OFFSET_TYPE])
if test "$MPI_OFFSET_TYPE" = "not found"; then
AC_MSG_WARN([*** Unable to find the right definition for MPI_Offset])
AC_MSG_ERROR([Cannot continue])
fi
AC_DEFINE_UNQUOTED(MPI_Offset, $MPI_OFFSET_TYPE, [Type of MPI_Offset])
#
# If we haven't already, figure out an MPI datatype that corresponds
# to the back-end C type of MPI_Offset.
#
AC_MSG_CHECKING([checking for an MPI datatype for MPI_Offset])
AC_MSG_RESULT([$MPI_OFFSET_DATATYPE])
if test "$MPI_OFFSET_DATATYPE" = "not found"; then
AC_MSG_WARN([*** Unable to find an MPI datatype corresponding to MPI_Offset])
AC_MSG_ERROR([Cannot continue])
fi
AC_DEFINE_UNQUOTED(OMPI_OFFSET_DATATYPE, $MPI_OFFSET_DATATYPE, [MPI datatype corresponding to MPI_Offset])
2003-11-22 19:36:58 +03:00
# all: endian
AC_WORDS_BIGENDIAN
OMPI_CHECK_BROKEN_QSORT
2003-11-22 19:36:58 +03:00
# all: SYSV semaphores
# all: SYSV shared memory
# all: size of FD_SET
# all: sizeof struct stat members
# all: type of getsockopt optlen
# all: type of recvfrom optlen
#
# Check out what thread support we have
#
OMPI_CONFIG_THREADS
CFLAGS="$CFLAGS $THREAD_CFLAGS"
CXXFLAGS="$CXXFLAGS $THREAD_CXXFLAGS"
CPPFLAGS="$CPPFLAGS $THREAD_CPPFLAGS"
CXXCPPFLAGS="$CXXCPPFLAGS $THREAD_CXXCPPFLAGS"
LDFLAGS="$LDFLAGS $THREAD_LDFLAGS"
LIBS="$LIBS $THREAD_LIBS"
WRAPPER_EXTRA_CFLAGS="$WRAPPER_EXTRA_CFLAGS $THREAD_CFLAGS"
WRAPPER_EXTRA_CXXFLAGS="$WRAPPER_EXTRA_CXXFLAGS $THREAD_CXXFLAGS"
WRAPPER_EXTRA_FFLAGS="$WRAPPER_EXTRA_FFLAGS $THREAD_FFLAGS"
WRAPPER_EXTRA_FCFLAGS="$WRAPPER_EXTRA_FCFLAGS $THREAD_FFLAGS"
WRAPPER_EXTRA_LDFLAGS="$WRAPPER_EXTRA_LDFLAGS $THREAD_LDFLAGS"
WRAPPER_EXTRA_LIBS="$WRAPPER_EXTRA_LIBS $THREAD_LIBS"
#
# What is the local equivalent of "ln -s"
#
AC_PROG_LN_S
#
# We need as and lex
#
AM_PROG_AS
AM_PROG_LEX
# If we don't have GNU Flex and we don't have a generated .c file
# (distribution tarballs will have the .c file included, but SVN
# checkouts will not), then error. Must have GNU Flex -- other
# versions of Lex are not workable (all things being equal, since this
# is *only* required for developers, we decided that it really was not
# worth it to be portable between different versions of lex ;-).
if test -z "$LEX" -o -n "`echo $LEX | grep missing`" -o \
"`basename $LEX`" != "flex"; then
if test ! -f "$srcdir/opal/util/show_help_lex.c"; then
AC_MSG_WARN([*** Could not find GNU Flex on your system.])
AC_MSG_WARN([*** GNU Flex required for developer builds of Open MPI.])
AC_MSG_WARN([*** Other versions of Lex are not supported.])
AC_MSG_WARN([*** YOU DO NOT NEED FLEX FOR DISTRIBUTION TARBALLS!])
AC_MSG_WARN([*** If you absolutely cannot install GNU Flex on this system])
AC_MSG_WARN([*** consider using a distribution tarball, or generate the])
AC_MSG_WARN([*** following files on another system (using Flex) and])
AC_MSG_WARN([*** copy them here:])
for lfile in `find . -name \*.l -print`; do
cfile="`echo $lfile | cut -d. -f-2`"
AC_MSG_WARN([*** $cfile.c])
done
AC_MSG_ERROR([Cannot continue])
fi
fi
#
# File system case sensitivity
#
OMPI_CASE_SENSITIVE_FS_SETUP
2003-11-22 19:36:58 +03:00
# AIX: FIONBIO in sys/ioctl.h
# glibc: memcpy
* Rewrite ompi_mca.m4 to use m4_defined lists of projects (ompi, orte, etc.), frameworks, and components without configure scripts instead of hard-coded shell variables (for projects and frameworks) and shell variable building (for components). * Add 3rd category of component configuration (in addition to configure scripts and no-configured components): configure.m4 components. These components can only be built as part of OMPI (like no-configure), but can provide an m4 file that is run as part of the main configure script. These macros can set whether the component should be built, along with just about any other configuration wanted. More care must be taken compared to configure components, as doing things like setting variables or calling AC_MSG_ERROR now affects the top-level configure script (so calling AC_MSG_ERROR if your component can't configure probably isn't what you want) * Added support to autogen.sh for the configure.m4-style components, as well as building up the m4_define lists ompi_mca.m4 now expects * Updated a number of macros to be more config.cache friendly (both so that config.cache can be used and so the test can be quickly run multiple times in the same configrue script): - ompi_config_asm - c_weak_symbols - c_get_alignment * Added new macros to be shared when configuring components: - ompi_objc.m4 (this actually provides AC_PROG_OBJC - don't ask...) - ompi_check_xgrid - ompi_check_tm - ompi_check_bproc * Updated a number of components to use configure.m4 instead of configure.stub - btl portals - io romio - tm ras and pls - bjs, lsf_bproc ras and bproc_seed pls - xgrid ras and pls - null iof (used by tm) This commit was SVN r6412.
2005-07-09 22:52:53 +04:00
# checkpoint results
AC_CACHE_SAVE
2003-11-22 19:36:58 +03:00
##################################
# MCA
##################################
ompi_show_title "Modular Component Architecture (MCA) setup"
AC_MSG_CHECKING([for subdir args])
OMPI_CONFIG_SUBDIR_ARGS([ompi_subdir_args])
AC_MSG_RESULT([$ompi_subdir_args])
OMPI_MCA
* Rewrite ompi_mca.m4 to use m4_defined lists of projects (ompi, orte, etc.), frameworks, and components without configure scripts instead of hard-coded shell variables (for projects and frameworks) and shell variable building (for components). * Add 3rd category of component configuration (in addition to configure scripts and no-configured components): configure.m4 components. These components can only be built as part of OMPI (like no-configure), but can provide an m4 file that is run as part of the main configure script. These macros can set whether the component should be built, along with just about any other configuration wanted. More care must be taken compared to configure components, as doing things like setting variables or calling AC_MSG_ERROR now affects the top-level configure script (so calling AC_MSG_ERROR if your component can't configure probably isn't what you want) * Added support to autogen.sh for the configure.m4-style components, as well as building up the m4_define lists ompi_mca.m4 now expects * Updated a number of macros to be more config.cache friendly (both so that config.cache can be used and so the test can be quickly run multiple times in the same configrue script): - ompi_config_asm - c_weak_symbols - c_get_alignment * Added new macros to be shared when configuring components: - ompi_objc.m4 (this actually provides AC_PROG_OBJC - don't ask...) - ompi_check_xgrid - ompi_check_tm - ompi_check_bproc * Updated a number of components to use configure.m4 instead of configure.stub - btl portals - io romio - tm ras and pls - bjs, lsf_bproc ras and bproc_seed pls - xgrid ras and pls - null iof (used by tm) This commit was SVN r6412.
2005-07-09 22:52:53 +04:00
# checkpoint results
AC_CACHE_SAVE
############################################################################
# Final top-level OMPI configuration
############################################################################
ompi_show_title "Final top-level OMPI configuration"
############################################################################
# Libevent setup
############################################################################
ompi_show_subtitle "Libevent 3rd party event handler"
CFLAGS_save="$CFLAGS"
CFLAGS="$OMPI_CFLAGS_BEFORE_PICKY"
OMPI_SETUP_LIBEVENT
CFLAGS="$CFLAGS_save"
2003-11-22 19:36:58 +03:00
############################################################################
# Libtool: part two
# (after C compiler setup)
############################################################################
ompi_show_subtitle "Libtool configuration"
2003-11-22 19:36:58 +03:00
# Use convenience libltdl for the moment, because we need to force the
# use of the newest libltdl (i.e., the one that ships with libtool
# 1.5) because it has support for a lot more things than older
# versions of libtool (which are generally installed by default).
AS_IF([test "$OMPI_ENABLE_DLOPEN_SUPPORT" = "1"],
[AC_LIBLTDL_CONVENIENCE(opal/libltdl)
AC_LIBTOOL_DLOPEN])
AC_SUBST(LTDLINCL)
AC_SUBST(LIBLTDL)
2003-11-22 19:36:58 +03:00
AM_PROG_LIBTOOL
# AC_CONFIG_SUBDIRS appears to be broken for non-gcc compilers (i.e.,
# passing precious variables down to the sub-configure).
#
# Note that we also did some magic scripty-foo in autogen.sh to rename
# the output libtool library "libompi_ltdl", so add -lompi_ltdl here.
# This is because so many systems have older versions of libltdl
# installed very early in ld.so's search path; if we installed our own
# libltdl in some non-standard path (e.g., $HOME/local or even
# /usr/local), the libltdl in /usr/lib might get found first. And if
# it's older -- or just not matching the version that we need, Bad
# Things happen. [sigh]
#
# Finally, make libompi_ltdl follow the same shared/static convention
# that was user for the main OMPI libraries. So manually examine
# $enable_shared and $enable_static and pass down the corresponding
# flags.
ompi_show_subtitle "GNU libltdl setup"
if test "$OMPI_ENABLE_DLOPEN_SUPPORT" = "1" ; then
ompi_subdir_args="$ompi_subdir_args --enable-ltdl-convenience --disable-ltdl-install"
if test "$enable_shared" = "yes"; then
ompi_subdir_args="$ompi_subdir_args --enable-shared"
else
ompi_subdir_args="$ompi_subdir_args --disable-shared"
fi
if test "$enable_static" = "yes"; then
ompi_subdir_args="$ompi_subdir_args --enable-static"
else
ompi_subdir_args="$ompi_subdir_args --disable-static"
fi
CFLAGS_save="$CFLAGS"
CFLAGS="$OMPI_CFLAGS_BEFORE_PICKY"
OMPI_CONFIG_SUBDIR(opal/libltdl, [$ompi_subdir_args], [HAPPY=1], [HAPPY=0])
if test "$HAPPY" = "1"; then
LIBLTDL_SUBDIR=libltdl
LIBLTDL_LTLIB=libltdl/libltdlc.la
WANT_LIBLTDL=1
# Arrgh. This is gross. But I can't think of any other way to do
# it. :-(
flags="`egrep ^LIBADD_DL opal/libltdl/Makefile | cut -d= -f2-`"
OMPI_CHECK_LINKER_FLAGS([opal/libltdl/libtool], [-export-dynamic $flags])
WRAPPER_EXTRA_LIBS="$WRAPPER_EXTRA_LIBS $extra_ldflags"
LDFLAGS="-export-dynamic $LDFLAGS"
else
LIBLTDL_SUBDIR=
LIBLTDL_LTLIB=
WANT_LIBLTDL=0
fi
CFLAGS="$CFLAGS_save"
else
AC_MSG_WARN([libltdl support disabled (by --disable-dlopen)])
LIBLTDL_SUBDIR=
LIBLTDL_LTLIB=
WANT_LIBLTDL=0
fi
AC_SUBST(LIBLTDL_SUBDIR)
AC_SUBST(LIBLTDL_LTLIB)
AM_CONDITIONAL(WANT_LIBLTDL, test "$WANT_LIBLTDL" = "1")
AC_DEFINE_UNQUOTED(OMPI_WANT_LIBLTDL, $WANT_LIBLTDL,
[Whether to include support for libltdl or not])
2003-11-22 19:36:58 +03:00
############################################################################
# final wrapper compiler config
############################################################################
ompi_show_subtitle "Wrapper compiler flags"
2003-11-22 19:36:58 +03:00
#
# This is needed for VPATH builds, so that it will -I the appropriate
# include directory (don't know why automake doesn't do this
# automatically). We delayed doing it until now just so that
# '-I$(top_srcdir)' doesn't show up in any of the configure output --
# purely aesthetic.
#
CPPFLAGS='-I$(top_srcdir)/include -I$(top_srcdir) -I$(top_builddir) -I$(top_builddir)/include -I$(top_srcdir)/opal -I$(top_srcdir)/orte -I$(top_srcdir)/ompi'" $CPPFLAGS"
CXXCPPFLAGS='-I$(top_srcdir)/include -I$(top_srcdir) -I$(top_builddir) -I$(top_builddir)/include -I$(top_srcdir)/opal -I$(top_srcdir)/orte -I$(top_srcdir)/ompi'" $CXXCPPFLAGS"
2003-11-22 19:36:58 +03:00
#
# Adding WRAPPER_* flags so that extra flags needed for wrappper compilers
#
# WRAPPER_EXTRA_CFLAGS
#
AC_MSG_CHECKING([for mpicc CFLAGS])
OMPI_UNIQ(WRAPPER_EXTRA_CFLAGS)
AC_SUBST(WRAPPER_EXTRA_CFLAGS)
AC_DEFINE_UNQUOTED(WRAPPER_EXTRA_CFLAGS, "$WRAPPER_EXTRA_CFLAGS",
[Additional CFLAGS to pass through the wrapper compilers])
AC_MSG_RESULT([$WRAPPER_EXTRA_CFLAGS])
#
# WRAPPER_EXTRA_CXXFLAGS
#
AC_MSG_CHECKING([for mpiCC CXXFLAGS])
OMPI_UNIQ(WRAPPER_EXTRA_CXXFLAGS)
AC_SUBST(WRAPPER_EXTRA_CXXFLAGS)
AC_DEFINE_UNQUOTED(WRAPPER_EXTRA_CXXFLAGS, "$WRAPPER_EXTRA_CXXFLAGS",
[Additional CXXFLAGS to pass through the wrapper compilers])
AC_MSG_RESULT([$WRAPPER_EXTRA_CXXFLAGS])
#
# WRAPPER_EXTRA_FFLAGS
#
AC_MSG_CHECKING([for mpif77/mpif90 FFLAGS])
OMPI_UNIQ(WRAPPER_EXTRA_FFLAGS)
AC_SUBST(WRAPPER_EXTRA_FFLAGS)
AC_DEFINE_UNQUOTED(WRAPPER_EXTRA_FFLAGS, "$WRAPPER_EXTRA_FFLAGS",
[Additional FFLAGS to pass through the wrapper compilers])
AC_MSG_RESULT([$WRAPPER_EXTRA_FFLAGS])
#
# WRAPPER_EXTRA_FCFLAGS
#
AC_MSG_CHECKING([for mpif77/mpif90 FCFLAGS])
OMPI_UNIQ(WRAPPER_EXTRA_FCFLAGS)
AC_SUBST(WRAPPER_EXTRA_FCFLAGS)
AC_DEFINE_UNQUOTED(WRAPPER_EXTRA_FCFLAGS, "$WRAPPER_EXTRA_FCFLAGS",
[Additional FCFLAGS to pass through the wrapper compilers])
AC_MSG_RESULT([$WRAPPER_EXTRA_FCFLAGS])
#
# WRAPPER_EXTRA_LDFLAGS
#
AC_MSG_CHECKING([for wrapper compiler LDFLAGS])
OMPI_UNIQ(WRAPPER_EXTRA_LDFLAGS)
AC_SUBST(WRAPPER_EXTRA_LDFLAGS)
AC_DEFINE_UNQUOTED(WRAPPER_EXTRA_LDFLAGS, "$WRAPPER_EXTRA_LDFLAGS",
[Additional LDFLAGS to pass through the wrapper compilers])
AC_MSG_RESULT([$WRAPPER_EXTRA_LDFLAGS])
#
# WRAPPER_EXTRA_LIBS
#
AC_MSG_CHECKING([for wrapper compiler LIBS])
AC_SUBST(WRAPPER_EXTRA_LIBS)
AC_DEFINE_UNQUOTED(WRAPPER_EXTRA_LIBS, "$WRAPPER_EXTRA_LIBS",
[Additional LIBS to pass through the wrapper compilers])
AC_MSG_RESULT([$WRAPPER_EXTRA_LIBS])
#
# Adding LIBMPI_* flags from the components that are necessary to
# compile with libmpi
#
# LIBMPI_EXTRA_LDFLAGS
#
AC_MSG_CHECKING([for libmpi additional LDFLAGS])
OMPI_UNIQ(LIBMPI_EXTRA_LDFLAGS)
AC_SUBST(LIBMPI_EXTRA_LDFLAGS)
AC_DEFINE_UNQUOTED(LIBMPI_EXTRA_LDFLAGS, "$LIBMPI_EXTRA_LDFLAGS",
[Additional LDFLAGS to compile against libmpi])
AC_MSG_RESULT([$LIBMPI_EXTRA_LDFLAGS])
#
# LIBMPI_EXTRA_LIBS
#
AC_MSG_CHECKING([for libmpi additional LIBS])
AC_SUBST(LIBMPI_EXTRA_LIBS)
AC_DEFINE_UNQUOTED(LIBMPI_EXTRA_LIBS, "$LIBMPI_EXTRA_LIBS",
[Additional LIBS to compile against libmpi])
AC_MSG_RESULT([$LIBMPI_EXTRA_LIBS])
#
# Delayed the substitution of CFLAGS and CXXFLAGS until now because
# they may have been modified throughout the course of this script.
#
2003-11-22 19:36:58 +03:00
AC_SUBST(CFLAGS)
AC_SUBST(CPPFLAGS)
AC_SUBST(CXXFLAGS)
AC_SUBST(CXXCPPFLAGS)
AC_SUBST(FFLAGS)
AC_SUBST(FCFLAGS)
2003-11-22 19:36:58 +03:00
############################################################################
# Party on
############################################################################
ompi_show_subtitle "Final output"
2003-11-22 19:36:58 +03:00
AM_CONFIG_HEADER([include/ompi_config.h])
2003-11-22 19:36:58 +03:00
AC_CONFIG_FILES([
Makefile
config/Makefile
include/Makefile
include/mpif.h
etc/Makefile
opal/Makefile
opal/include/Makefile
opal/include/sys/Makefile
opal/include/sys/alpha/Makefile
opal/include/sys/amd64/Makefile
opal/include/sys/ia32/Makefile
opal/include/sys/ia64/Makefile
opal/include/sys/mips/Makefile
opal/include/sys/powerpc/Makefile
opal/include/sys/sparc/Makefile
opal/include/sys/sparcv9/Makefile
opal/include/sys/win32/Makefile
opal/asm/Makefile
opal/class/Makefile
opal/event/Makefile
opal/event/compat/Makefile
opal/event/compat/sys/Makefile
opal/runtime/Makefile
opal/threads/Makefile
opal/util/Makefile
opal/mca/Makefile
opal/mca/base/Makefile
orte/Makefile
orte/include/Makefile
orte/class/Makefile
orte/dps/Makefile
orte/runtime/Makefile
orte/util/Makefile
orte/tools/Makefile
orte/tools/console/Makefile
orte/tools/orted/Makefile
orte/tools/orteprobe/Makefile
orte/tools/orterun/Makefile
orte/tools/openmpi/Makefile
orte/mca/Makefile
orte/dynamic-mca/Makefile
ompi/Makefile
ompi/include/Makefile
ompi/class/Makefile
ompi/attribute/Makefile
ompi/communicator/Makefile
ompi/datatype/Makefile
ompi/errhandler/Makefile
ompi/file/Makefile
ompi/group/Makefile
ompi/info/Makefile
ompi/op/Makefile
ompi/proc/Makefile
ompi/request/Makefile
ompi/runtime/Makefile
ompi/win/Makefile
ompi/mpi/Makefile
ompi/mpi/c/Makefile
ompi/mpi/c/profile/Makefile
ompi/mpi/cxx/Makefile
ompi/mpi/f77/Makefile
ompi/mpi/f77/profile/Makefile
ompi/mpi/f90/Makefile
ompi/mpi/f90/fortran_kinds.sh
ompi/mpi/f90/fortran_sizes.h
ompi/mpi/f90/scripts/Makefile
ompi/tools/Makefile
ompi/tools/ompi_info/Makefile
ompi/tools/wrappers/Makefile
ompi/mca/Makefile
ompi/dynamic-mca/Makefile
test/Makefile
test/asm/Makefile
test/class/Makefile
test/dps/Makefile
test/mca/Makefile
test/mca/gpr/Makefile
test/mca/ns/Makefile
test/mca/oob/Makefile
test/mca/ras/Makefile
test/mca/rds/Makefile
test/mca/rmaps/Makefile
test/mca/schema/Makefile
test/runtime/Makefile
test/support/Makefile
test/threads/Makefile
test/util/Makefile
2003-11-22 19:36:58 +03:00
])
AC_OUTPUT